# Why is math.sqrt() incorrect for large numbers?

Why does the `math` module return the wrong result?

## First test

``````A = 12345678917
print 'A =',A
B = sqrt(A**2)
print 'B =',int(B)
``````

Result

``````A = 12345678917
B = 12345678917
``````

Here, the result is correct.

## Second test

``````A = 123456758365483459347856
print 'A =',A
B = sqrt(A**2)
print 'B =',int(B)
``````

Result

``````A = 123456758365483459347856
B = 123456758365483467538432
``````

Here the result is incorrect.

Why is that the case?

• Floating point precision. Jan 9, 2017 at 15:41
• I know, but how to fix it? Jan 9, 2017 at 15:43
• `int(float(123456758365483459347856)) == 123456758365483459347856 -> False` Jan 9, 2017 at 15:44
• I haven't tried it myself but perhaps the decimal library might be of use?
– Tagc
Jan 9, 2017 at 15:46
• Related: Is floating point math broken? Jan 20, 2022 at 3:07

Because `math.sqrt(..)` first casts the number to a floating point and floating points have a limited mantissa: it can only represent part of the number correctly. So `float(A**2)` is not equal to `A**2`. Next it calculates the `math.sqrt` which is also approximately correct.

Most functions working with floating points will never be fully correct to their integer counterparts. Floating point calculations are almost inherently approximative.

If one calculates `A**2` one gets:

``````>>> 12345678917**2
152415787921658292889L
``````

Now if one converts it to a `float(..)`, one gets:

``````>>> float(12345678917**2)
1.5241578792165828e+20
``````

But if you now ask whether the two are equal:

``````>>> float(12345678917**2) == 12345678917**2
False
``````

So information has been lost while converting it to a float.

You can read more about how floats work and why these are approximative in the Wikipedia article about IEEE-754, the formal definition on how floating points work.

The documentation for the math module states "It provides access to the mathematical functions defined by the C standard." It also states "Except when explicitly noted otherwise, all return values are floats."

Those together mean that the parameter to the square root function is a float value. In most systems that means a floating point value that fits into 8 bytes, which is called "double" in the C language. Your code converts your integer value into such a value before calculating the square root, then returns such a value.

However, the 8-byte floating point value can store at most 15 to 17 significant decimal digits. That is what you are getting in your results.

If you want better precision in your square roots, use a function that is guaranteed to give full precision for an integer argument. Just do a web search and you will find several. Those usually do a variation of the Newton-Raphson method to iterate and eventually end at the correct answer. Be aware that this is significantly slower that the math module's sqrt function.

Here is a routine that I modified from the internet. I can't cite the source right now. This version also works for non-integer arguments but just returns the integer part of the square root.

``````def isqrt(x):
"""Return the integer part of the square root of x, even for very
large values."""
if x < 0:
raise ValueError('square root not defined for negative numbers')
n = int(x)
if n == 0:
return 0
a, b = divmod(n.bit_length(), 2)
x = (1 << (a+b)) - 1
while True:
y = (x + n//x) // 2
if y >= x:
return x
x = y
``````

If you want to calculate sqrt of really large numbers and you need exact results, you can use `sympy`:

``````import sympy

num = sympy.Integer(123456758365483459347856)

print(int(num) == int(sympy.sqrt(num**2)))
``````

The way floating-point numbers are stored in memory makes calculations with them prone to slight errors that can nevertheless be significant when exact results are needed. As mentioned in one of the comments, the `decimal` library can help you here:

``````>>> A = Decimal(12345678917)
>>> A
Decimal('123456758365483459347856')
>>> B = A.sqrt()**2
>>> B
Decimal('123456758365483459347856.0000')
>>> A == B
True
>>> int(B)
123456758365483459347856
``````

I use version 3.6, which has no hardcoded limit on the size of integers. I don't know if, in 2.7, casting `B` as an `int` would cause overflow, but `decimal` is incredibly useful regardless.